System Modeling - Industries - Mentor Graphics

Model-driven development describes a top-down, multi-discipline, concurrent design methodology that uses a hardware/software co-development environment to model, simulate, and analyze complex medical systems. System modeling tools from Mentor Graphics allow models from different domains to be integrated at each phase of the design flow, allowing system integration issues to be identified and addressed earlier, and helping to reduce overall program time and costs in the design of complex medical electronic devices.

System modeling technology from Mentor Graphics enables engineers to capture requirements and simulate the behavior and interactions of proposed systems and components in the context of a vehicle’s electronic and physical environments. Model-driven development techniques allow problems to be discovered early and subsystems to integrate and work together. System design tools help the user control the increasing complexity of designing and manufacturing today’s vehicles.

System modeling, simulation and analysis tools from Mentor Graphics allow our mil/aero customers to design digital devices that meet or exceed their rigorous standards. They allow the user to avoid cost overruns, schedule delays, low reliability, and even product failures related to the development of large-scale, safety-critical systems and platforms.

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Improved automation is also needed in the design of electrical, electronic and embedded software components, which require a stable and reliable software development environment for modeling, simulation, verification and testing of software interfaced to actual hardware.

A virtual prototyping infrastructure in which models from different domains can be integrated at each stage of the development life cycle allows system integration issues to be identified and addressed earlier, helping reduce overall program time and cost.

A multi-discipline development environment and concurrent design methodology provide continuity throughout the design, implementation, and validation phases of system development.
Hardware and software development progresses in-sync, ensuring that changes in one development flow can immediately be analyzed for effects in complementary flows.

Virtual system integration can take place at the time of system requirements definition or during preliminary or detailed design, allowing critical problems to be uncovered well before final system integration.
True system modeling provides an interactive environment in which designers can verify their specific part of an overall puzzle, a puzzle in which any small change can affect the final outcome.

Designers can use model-driven system development to test and verify their complex system designs to be compatible with harsh operating environments and compliant with strict reliability requirements.
You can avoid cost overruns, schedule delays, low reliability, and even product failures related to the development of large-scale systems and platforms.